What is the Standard Model?
The Standard Model in particle physics definitely does not suggest that the answer to life, the universe and everything is 42. However, it does give physicists a profound understanding of what life, the universe and everything is made up of. It describes the fundamental particles that essentially make up all matter and the forces that act upon them. CERN state that, “how these particles and three of the forces are related to each other is encapsulated in the Standard Model of particle physics.”
Even though the Standard Model was a cumulative effort of scientists around the world for many years, the term itself was coined in the 1970s. They categorised the basic elementary particles, quarks and leptons, into six groups which are then paired and called `generations` based on their weight and stability. The lightest and most stable particles are called the first generation and they make up all stable matter in the universe. The Standard Model has been used to not only identify different types of particles, but also to predict their existence. Over the years, its reliability at predicting the existence of particles has been proven time and time again as these particles have subsequently been discovered.
There are four Fundamental forces that are exerted on these elementary particles and they are the strong force, the weak force, the electromagnetic force and the gravitational force. Interestingly, the Standard Model includes all of these forces except gravity. Being the best known force to the average person, it seems odd that this force is not included but it does not fit comfortably into the Standard Model and this is partly due to the fact that gravitational force is so weak when exerted on particles that its effect is negligible. Each of the other forces works by matter particles exchanging force-carrier particles called `bosons`. Different forces have different bosons. The strong force has one called `gluons` while the weak force is carried by the `W and Z bosons`. Electromagnetic force is carried by `protons` but, although it is thought that gravity should have a force-carrying particle called a `graviton`, it has never been discovered.
Beyond the Standard Model
This is an example of how the Standard Model is “still incomplete” as CERN state. It cannot explain dark matter and CERN suggests that it is “part of a bigger picture that includes new physics hidden deep in the subatomic world or in the dark recesses of the universe”. There are a large number of experiments going on currently that test theories within and beyond the Standard Model. The most famous being the attempts to discover the Higgs boson particle in the Large Hadron Collider at CERN. However, many other such experiments are taking place all over the world using vacuum conditions to isolate particles.